CN110260620B

CN110260620B - Peat drying dehydration processing system

Info

Publication number: CN110260620B
Application number: CN201910578956.2A
Authority: CN
Inventors: 毛利英
Original assignee: Xinxiang Yueheng Electronic Information Technology Co Ltd
Current assignee: Xinxiang Yueheng Electronic Information Technology Co ltd
Priority date: 2019-06-28
Filing date: 2019-06-28
Publication date: 2020-11-03
Anticipated expiration: 2039-06-28
Also published as: CN110260620A

Abstract

The invention discloses a peat drying and dehydrating treatment system, which comprises a treatment box and a cavity arranged in the treatment box, wherein a feeding pipe is fixedly arranged in the top wall of the cavity, a cylindrical box is fixedly arranged in the cavity, a rotating cavity is arranged in the cylindrical box, the top wall of the rotating cavity is provided with an upper hole communicated with a pipe cavity, a rotatable gear shaft is arranged in the rotating cavity, two rotating shafts are rotatably arranged on the outer circular surface of the gear shaft, and one end of each rotating shaft is fixedly provided with a dehydrating box. So as to be used continuously and save cost.

Description

Peat drying dehydration processing system

Technical Field

The invention relates to the technical field of peat drying, in particular to a peat drying and dehydrating treatment system.

Background

Peat is also called turf or peat, is a loose organic matter accumulation which is formed by incompletely decomposed plant residues, humic substances, mineral substances and the like through biological and chemical actions in a soaking environment and an anoxic environment, is mostly brown and blackish brown, can be changed into lignite through further diagenesis, is a poor-layer early-generation coal growing in an ancient stratum, is a sapropel coal formed by lower organisms such as algae, fungi and the like in a shallow sea environment, is rich in a plurality of beneficial components such as protein, humic acid, mineral substances and the like, has good water physical, chemical and biological properties, and is used as a fuel in daily life in a production place;

before the peat is used as fuel, the peat needs to be dehydrated and dried, the existing peat drying is generally carried out by heating in a roller, the effect of the mode is general, and the invention improves the defects.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a peat drying and dewatering treatment system, which overcomes the problems.

The invention is realized by the following technical scheme.

The peat drying and dewatering treatment system comprises a treatment box and a cavity arranged in the treatment box, wherein a feeding pipe is fixedly arranged in the top wall of the cavity, a pipe cavity is formed in the feeding pipe, a valve mechanism is arranged in the pipe cavity, a cylindrical box is fixedly arranged in the cavity, a rotating cavity is arranged in the cylindrical box, and an upper hole communicated with the pipe cavity is formed in the top wall of the rotating cavity;

a rotatable gear shaft is arranged in the rotary cavity, two rotary shafts are rotatably arranged on the outer circular surface of the gear shaft, a dewatering box is fixedly arranged at one end of each rotary shaft, a dewatering cavity with an opening at one side is arranged in each dewatering box, and peat enters the dewatering cavities through the feeding pipe and the upper hole when the valve mechanism is opened;

an electric heating plate is fixedly arranged on the inner wall of the dehydration cavity, peat is heated under the action of the electric heating plate after entering the dehydration cavity, so that moisture in the peat is evaporated, a stirring mechanism is arranged in the dehydration cavity, limiting grooves communicated with the outside are formed in the inner wall of the dehydration cavity, four limiting grooves are formed along the circumferential direction of the dehydration box, an installation box is detachably installed in each limiting groove, a drying agent cavity with an opening at one side is formed in the installation box, a filtering membrane is fixedly arranged on one side of the opening of the drying agent cavity, a silica gel drying agent is installed in the drying agent cavity, and moisture emitted by the peat is absorbed by the silica gel drying agent in the drying agent cavity;

a lower hole which penetrates through the bottom wall of the cylindrical box from top to bottom is formed in the bottom wall of the cylindrical box, a discharge pipe communicated with the lower hole is fixedly arranged on the lower end face of the cylindrical box, and when the dewatering box rotates to enable the dewatering cavity to be communicated with the discharge pipe, dewatered and dried peat in the dewatering cavity is discharged through the discharge pipe;

and a reduction mechanism capable of reducing the silica gel drying agent is arranged in the cavity.

Further, be equipped with the power chamber in the treatment box, the power chamber with rotatory chamber intercommunication, the gear shaft left end extends to in the power chamber, be equipped with in the power chamber with gear shaft fixed connection's gear, the fixed motor that is equipped with of power chamber left side wall, motor right side power is connected with the power shaft, the fixed band pulley that is equipped with of power shaft right-hand member, power chamber left side wall rotates and is equipped with and is located the lower pivot of gear shaft downside, the fixed band pulley that is equipped with of lower pivot right-hand member, the band pulley down the outer disc of band pulley all is equipped with the ring channel, go up the band pulley with connect through belt drive between the band pulley down, the fixed first rack that is equipped with on the band pulley, after the motor starts, first rack can with gear engagement.

Further, valve mechanism including set up in the closed ball in the lumen, the perforating hole that runs through around being equipped with in the closed ball, the inlet pipe left side be equipped with closed ball fixed connection's installation axle, drive when the installation axle rotates the closed ball rotates and makes the cavity with the lumen intercommunication.

Furthermore, the left end of the installation shaft extends into the power cavity, a transmission gear is fixedly arranged at the left end of the installation shaft, a second rack which can be meshed with the transmission gear is fixedly arranged on the belt, when the belt rotates, the first rack is firstly meshed with the gear, so that any one of the dewatering cavities is communicated with the upper hole, then the first rack is separated from the gear, and the second rack is meshed with the transmission gear, so that the cavities are communicated with the pipe cavity.

Furthermore, the reduction mechanism comprises a reduction cavity which is arranged in the cavity right wall and is communicated with the cavity, a microwave generator is fixedly arranged on the upper wall and the lower wall of the reduction cavity, an electric push rod is fixedly arranged on the right wall of the reduction cavity, an arc-shaped plate is fixedly arranged at the left end of the push rod on the electric push rod, electromagnets are symmetrically and fixedly arranged on the front and back of the left end face of the arc-shaped plate, when the electric push rod is started, the electromagnets are abutted to the installation box, and after the electromagnets are electrified, the electric push rod is started to reset to transport the installation box to the reduction cavity, so that reduction is completed under the action of the microwave generator.

Further, a transmission bevel gear is fixedly arranged on the rotating shaft, a connecting shaft fixedly connected with the sealing ball is rotatably arranged on the right wall of the cavity, a sliding groove is formed in the right wall of the cavity, a control electromagnet is fixedly arranged on the top wall of the sliding groove, a sliding block is slidably arranged in the sliding groove, a spring is connected between the sliding block and the bottom wall of the sliding groove, a transmission shaft is rotatably arranged on the left end face of the sliding block, the transmission shaft is in transmission connection with the connecting shaft through a belt wheel mechanism, and a driving bevel gear capable of being meshed with the transmission bevel gear is fixedly arranged at the left end of the transmission.

Furthermore, a limiting ring is fixedly arranged on the end face of the outer side of the installation box.

Further, the stirring mechanism comprises a motor arranged in the inner wall of the dehydration cavity, one side of the motor is in power connection with a stirring shaft extending into the dehydration cavity, and stirring blades are fixedly arranged on the stirring shaft.

The invention has the beneficial effects that: after the peat enters the drying device, the drying device can stir and heat the peat, the heating temperature is lower than that of a traditional roller, energy is saved, moisture of the peat is evaporated after the peat is heated, the peat is absorbed by the silica gel drying agent arranged in the drying device, a good drying effect is achieved, and the silica gel drying agent can be automatically reduced after the peat is used for a period of time so as to be used continuously, and cost is saved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the structure at A-A in FIG. 1;

FIG. 3 is a schematic view of the structure at B-B in FIG. 1;

FIG. 4 is a schematic view of the structure at C-C in FIG. 2;

fig. 5 is a top view of the arcuate plate 25 of fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The peat drying and dewatering treatment system described with reference to fig. 1-5 mainly includes a treatment tank 10 and a cavity 42 disposed in the treatment tank 10, wherein a feed pipe 40 is fixedly disposed in a top wall of the cavity 42, a pipe cavity 50 is disposed in the feed pipe 40, a valve mechanism 90 is disposed in the pipe cavity 50, a cylindrical tank 23 is fixedly disposed in the cavity 42, a rotary chamber 22 is disposed in the cylindrical tank 23, and an upper hole 48 communicated with the pipe cavity 50 is disposed in a top wall of the rotary chamber 22;

a rotatable gear shaft 30 is arranged in the rotary cavity 22, two rotating shafts 33 are rotatably arranged on the outer circular surface of the gear shaft 30, one end of each rotating shaft 33 is fixedly provided with a dewatering box 21, a dewatering cavity 61 with an opening at one side is arranged in each dewatering box 21, and when the valve mechanism 90 is opened, peat enters the dewatering cavities 61 through the feeding pipe 40 and the upper hole 48;

an electric heating plate 46 is fixedly arranged on the inner wall of the dehydration cavity 61, peat is heated under the action of the electric heating plate 46 after entering the dehydration cavity 61, so that moisture in the peat is evaporated, a stirring mechanism is arranged in the dehydration cavity 61, limiting grooves 57 communicated with the outside are arranged in the inner wall of the dehydration cavity 61, four limiting grooves 57 are arranged along the circumferential direction of the dehydration box 21, an installation box 26 is detachably installed in each limiting groove 57, a drying agent cavity 56 with an opening at one side is arranged in each installation box 26, a filtering membrane 54 is fixedly arranged at one opening side of each drying agent cavity 56, silica gel drying agents are installed in each drying agent cavity 56, and moisture emitted by the peat is absorbed by the silica gel drying agents in the drying agent cavities 56;

a lower hole 45 which penetrates through the bottom wall of the cylindrical box 23 up and down is arranged in the bottom wall of the cylindrical box 23, a discharge pipe 24 which is communicated with the lower hole 45 is fixedly arranged on the lower end surface of the cylindrical box 23, and when the dewatering box 21 rotates to enable the dewatering cavity 61 to be communicated with the discharge pipe 24, dewatered and dried peat in the dewatering cavity 61 is discharged through the discharge pipe 24;

the cavity 42 is provided with a reduction mechanism 91 capable of reducing the silica gel desiccant.

A power cavity 36 is arranged in the processing box 10, the power cavity 36 is communicated with the rotating cavity 22, the left end of the gear shaft 30 extends into the power cavity 36, a gear 31 fixedly connected with the gear shaft 30 is arranged in the power cavity 36, a motor 37 is fixedly arranged on the left wall of the power cavity 36, a power shaft 52 is connected to the right side of the motor 37, the right end of the power shaft 52 is fixedly provided with an upper belt wheel 39, the left wall of the power cavity 36 is rotatably provided with a lower rotating shaft 27 positioned at the lower side of the gear shaft 30, a lower belt wheel 28 is fixedly arranged at the right end of the lower rotating shaft 27, annular grooves 38 are respectively arranged on the outer circular surfaces of the lower belt wheel 28 and the upper belt wheel 39, the upper belt wheel 39 and the lower belt wheel 28 are in transmission connection through a belt 29, a first rack 34 is fixedly arranged on the belt 29, and after the motor 37 is started, the first rack 34 can be meshed with the gear 31.

The valve mechanism 90 comprises a sealing ball 49 arranged in the tube cavity 50, a through hole 43 penetrating through the sealing ball 49 is formed in the sealing ball 49, an installation shaft 51 fixedly connected with the sealing ball 49 is arranged on the left side of the feeding pipe 40, and the installation shaft 51 drives the sealing ball 49 to rotate to enable the cavity 42 to be communicated with the tube cavity 50 when rotating.

The left end of the installation shaft 51 extends into the power cavity 36, a transmission gear 35 is fixedly arranged at the left end of the installation shaft 51, a second rack 53 which can be meshed with the transmission gear 35 is fixedly arranged on the belt 29, when the belt 29 rotates, the first rack 34 is firstly meshed with the gear 31, so that any one of the dehydration cavities 61 is communicated with the upper hole 48, then the first rack 34 is separated from the gear 31, and the second rack 53 is meshed with the transmission gear 35, so that the cavity 42 is communicated with the tube cavity 50.

The reduction mechanism 91 comprises a reduction cavity 19 which is arranged in the right wall of the cavity 42 and communicated with the cavity 42, a microwave generator 18 is fixedly arranged on the upper wall and the lower wall of the reduction cavity 19, an electric push rod 20 is fixedly arranged on the right wall of the reduction cavity 19, an arc-shaped plate 25 is fixedly arranged at the left end of a push rod 60 on the left side of the electric push rod 20, electromagnets 59 are symmetrically and fixedly arranged on the front and back of the left end face of the arc-shaped plate 25, when the electric push rod 20 is started, the electromagnets 59 can be abutted against the installation box 26, after the electromagnets 59 are electrified, the electric push rod 20 is started to reset, the installation box 26 is conveyed into the reduction cavity 19, and reduction is completed under the action of the microwave.

The driving bevel gear 32 is fixedly arranged on the rotating shaft 33, a connecting shaft 41 fixedly connected with the sealing ball 49 is rotatably arranged on the right wall of the cavity 42, a sliding groove 13 is formed in the right wall of the cavity 42, a control electromagnet 12 is fixedly arranged on the top wall of the sliding groove 13, a sliding block 14 is slidably arranged in the sliding groove 13, a spring 15 is connected between the sliding block 14 and the bottom wall of the sliding groove 13, a transmission shaft 17 is rotatably arranged on the left end face of the sliding block 14, the transmission shaft 17 is in transmission connection with the connecting shaft 41 through a belt wheel mechanism 16, and a driving bevel gear 11 capable of being meshed with the driving bevel gear 32 is fixedly arranged at the left end of the transmission.

A limiting ring 55 is fixedly arranged on the end face of the outer side of the mounting box 26.

The stirring mechanism comprises a motor 58 arranged in the inner wall of the dehydration cavity 61, one side of the motor 58 is in power connection with a stirring shaft 47 extending into the dehydration cavity 61, and a stirring blade 44 is fixedly arranged on the stirring shaft 47.

Sequence of mechanical actions of the whole device:

1. the motor 37 is started to enable the upper belt wheel 39 to drive the belt 29 to rotate, the first rack 34 and the gear 31 are meshed to drive the gear shaft 30 to rotate, and the gear shaft 30 drives a dewatering cavity 61 to be communicated with the upper hole 48 through the rotating shaft 33;

2. the first rack 34 is separated from the gear 31, the second rack 53 is meshed with the transmission gear 35 to drive the mounting shaft 51 to rotate, the mounting shaft 51 drives the sealing ball 49 to rotate so that the through hole 43 is communicated with the pipe cavity 50, the motor 37 stops, and peat enters the dewatering cavity 61 through the feeding pipe 40;

3. after a period of time, the motor 37 is started, the first rack 34 is meshed with the transmission gear 35 to enable the sealing ball 49 to rotate to seal the pipe cavity 50, the second rack 53 is meshed with the gear 31 to enable the dewatering box 21 to rotate ninety degrees, and the motor 37 is stopped;

4. the electric heating plate 46 is started to start heating, the motor 58 is started to drive the stirring blades 44 to rotate through the stirring shaft 47 for stirring, and the moisture in the dehydration cavity 61 is absorbed by the silica gel desiccant in the desiccant cavity 56;

5. after a period of time, the motor 37 is started again to repeat the step 2, the dehydration cavity 61 filled with dehydrated peat rotates to be communicated with the discharge pipe 24, and the peat is discharged through the discharge pipe 24;

6. the electric push rod 20 is started to enable the arc-shaped plate 25 to move leftwards so that the electromagnet 59 abuts against the two installation boxes 26, the electromagnet 59 is started to attract the installation boxes 26, the electric push rod 20 is started to reset to convey the installation boxes 26 into the reduction cavity 19, the microwave generator 18 emits microwaves to bake the silica gel drying agent so that the silica gel drying agent is reduced, and the electric push rod 20 is started again to install the installation boxes 26 in the limiting groove 57;

7. when the dewatering box 21 rotates to the upper side again, the control electromagnet 12 is powered off and does not attract the sliding block 14, the sliding block 14 descends under the action of the spring 15 to enable the driving bevel gear 11 to be meshed with the transmission bevel gear 32, when the mounting shaft 51 rotates, the connecting shaft 41 is driven to rotate through the sealing ball 49, the driving bevel gear 11 is driven to rotate through the belt wheel mechanism 16 and the transmission shaft 17, the driving bevel gear 11 drives the transmission bevel gear 32 to rotate to enable the dewatering box 21 to rotate by ninety degrees, and when the dewatering box 21 rotates to the lower side again, the silica gel drying agents in the other two mounting boxes 26 are restored.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a dry dehydration processing system of peat, including handling the case and set up in cavity in the case of handling, its characterized in that: a feeding pipe is fixedly arranged in the top wall of the cavity, a pipe cavity is arranged in the feeding pipe, a valve mechanism is arranged in the pipe cavity, a cylindrical box is fixedly arranged in the cavity, a rotating cavity is arranged in the cylindrical box, and an upper hole communicated with the pipe cavity is formed in the top wall of the rotating cavity;

2. The peat drying and dewatering processing system according to claim 1, wherein: be equipped with the power chamber in the treatment box, the power chamber with rotatory chamber intercommunication, the gear shaft left end extends to in the power chamber, be equipped with in the power chamber with gear shaft fixed connection's gear, the fixed motor that is equipped with of power chamber left side wall, motor right side power is connected with the power shaft, the fixed band pulley that is equipped with of power shaft right-hand member, power chamber left side wall rotates and is equipped with and is located the lower pivot of gear shaft downside, the fixed band pulley that is equipped with of lower pivot right-hand member, the band pulley down the outer disc of last band pulley all is equipped with the ring channel, go up the band pulley with connect through belt drive between the band pulley down, the fixed first rack that is equipped with on the band pulley, after the motor starts, first rack can with gear engagement.

3. The peat drying and dewatering processing system according to claim 2, wherein: the valve mechanism comprises a sealing ball arranged in the tube cavity, a through hole penetrating through the sealing ball is formed in the sealing ball, an installation shaft fixedly connected with the sealing ball is arranged on the left side of the feeding pipe, and the installation shaft drives the sealing ball to rotate to enable the cavity to be communicated with the tube cavity.

4. The peat drying and dewatering processing system according to claim 3, wherein: the utility model discloses a dehydration cavity, including installation axle, drive gear, belt, first rack, second rack, drive gear, first rack, second rack, the installation axle left end extends to in the power chamber, the installation axle left end is fixed and is equipped with drive gear, the belt on be fixed be equipped with can with drive gear meshing second rack, when the belt is rotatory, first rack earlier with gear engagement makes arbitrary one dehydration cavity with the upper aperture intercommunication, afterwards first.

5. The peat drying and dewatering processing system according to claim 4, wherein: the reduction mechanism comprises a reduction cavity which is arranged in the cavity right wall and communicated with the cavity, a microwave generator is fixedly arranged on the upper wall and the lower wall of the reduction cavity, an electric push rod is fixedly arranged on the right wall of the reduction cavity, an arc-shaped plate is fixedly arranged at the left end of the push rod of the electric push rod, electromagnets are symmetrically and fixedly arranged on the front side and the rear side of the left end face of the arc-shaped plate, when the electric push rod is started, the electromagnets are abutted to an installation box, and after the electromagnets are electrified, the electric push rod is started to reset, so that the installation box is conveyed to the reduction cavity, and reduction is completed under the action of the microwave.

6. The peat drying and dewatering processing system according to claim 5, wherein: the automatic sealing device is characterized in that a transmission bevel gear is fixedly arranged on the rotating shaft, a connecting shaft fixedly connected with the sealing ball is rotatably arranged on the right wall of the cavity, a sliding groove is formed in the right wall of the cavity, a control electromagnet is fixedly arranged on the top wall of the sliding groove, a sliding block is slidably arranged in the sliding groove, a spring is connected between the sliding block and the bottom wall of the sliding groove, a transmission shaft is rotatably arranged on the left end face of the sliding block, the transmission shaft is in transmission connection with the connecting shaft through a belt wheel mechanism, and a driving bevel gear capable of being meshed with the transmission bevel gear.

7. The peat drying and dewatering processing system according to claim 1, wherein: and a limiting ring is fixedly arranged on the end face of the outer side of the installation box.

8. The peat drying and dewatering processing system according to claim 1, wherein: the stirring mechanism comprises a motor arranged in the inner wall of the dehydration cavity, one side of the motor is in power connection with a stirring shaft extending into the dehydration cavity, and stirring blades are fixedly arranged on the stirring shaft.